Water and life substances
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Transcript of Water and life substances
Water and its Importance
• Water makes up 70 to 95 percent of most organisms.
• When atoms form covalent bonds, and they do not share the electrons equally. It forms a polar molecule
• A POLAR MOLECULE is a molecule with an unequal distribution of charge; that is, each molecule has a positive end and a negative end.
Water and its importance
• Water is an example of a polar molecule. Polar water molecules attract ions as well as other polar molecules.
• Because of this attraction, water can dissolve many ionic compounds, such as salt, and many other polar molecules, such as sugar.
Water and its importance
• Water molecules also attract other water molecules.
• The positively charge hydrogen atoms of one water molecule attract the negatively charged oxygen atoms of another water molecule.
• This attraction of opposite charge between hydrogen and oxygen forms a weak bond called Hydrogen bonds.
Water and its importance
Water and its Importance
• Water resists changes in temperature. Therefore, water requires more heat to increase its temperature than do most other common liquids.
• Water is like an insulator that helps maintain steady environment when conditions fluctuate. Water is extremely important to cellular functions as it helps cells maintain homeostasis.
Life substances
• A carbon atom has four electrons available for bonding in its outer energy level.
• In order to become stable, a carbon atom forms four covalent bonds that fill it’s outer energy level.
• When carbon bonds with another carbon is forms a single bond.
Life substances
• When each atom share two electrons, a double bond is formed.
When each atom shares three electrons, a triple bond is formed.
Life substances
• When carbon atoms bond to each other, they can form straight chains, branched chains, or rings.
• Chemical formula: C6H12O6
• Compounds that have the same chemical formula but different three-dimensional structures are called Isomers.
Life substances
Molecular chains
• Carbon compounds vary greatly in size. Some contain just one or two carbon atoms, whereas others contain tens, hundreds or even thousands of carbon atoms.
• These large organic compounds are called biomolecules.
Example of a biomolecule is protein.
Molecular chains
• Cells build biomolecules by bonding small molecules together to form chains called polymers.
• A polymer is a large molecule formed when many smaller molecules bond together.
• Polymers can be formed by condensation and a water molecule is released.
• Polymers can be broken apart in the process called hydrolysis. A water molecule is attached between the subunits.
The structure of carbohydrates
• Carbohydrates are used by cells to provide energy.
• A carbohydrate is a biomolecule composed of carbon, hydrogen, and oxygen with a ratio of about 2 hydrogen atoms and 1 oxygen atom for every carbon.
• The simplest type of carbohydrate is a simple sugar called monosacharide.
Carbohydrates
• Common examples of are the isomers glucose and fructose.
• 2 monosaccharide molecules can combine to form a disaccharide, a two sugar carbohydrate.
• The largest carbohydrates molecules are polysaccharides, polymers composed of man monosaccharide subunits.
Carbohydrates
• Examples of polysaccharides are starch, glycogen, and cellulose.
• Starch is used as energy storage by plant cells and as food reservoirs in seeds and bulbs
• Mammals store energy in liver in the form of glycogen
• Cellulose forms the cell walls of plants and gives plants structural support.
• Starch
• Cellulose
• Glycogen
The Structure of Proteins
• Proteins provide structure for tissues and organs and carry out cell metabolism.
• A protein is a large, complex polymer composed of carbon, hydrogen, oxygen, nitrogen, and sometimes sulfur.
• The basic building blocks of proteins are called amino acids.
• These building blocks, in various combinations, make thousands of proteins
proteins
• Amino acid are linked together when an H from the amino group of one aa and an OH group from carboxyl group of another aa are removed to form a water molecule.
Protein
• The covalent bond formed between the amino acids is called a peptide bond.
• Proteins come in different shapes and sizes.
• The number and sequence of aa that make up a protein are important in determining its shape.
• Certain proteins are acidic, some are basic, and some are not charged.
• These properties cause the aa to attract or repel each other in different ways.
Protein
• Many proteins consist of two or more aa chains that are held together by hydrogen bonds.
• The 3D shape that the protein folds into is extremely important to the function of the protein.
• If the sequence of amino acids in the protein were to change, the protein might fold differently and not be able to carry out its function in the cell.
Proteins
• Proteins are also important in the contracting of muscle tissue, transporting oxygen in the bloodstream, providing immunity, regulating other proteins and carrying out chemical reactions.
• An enzyme protein that changes that rate of chemical reaction. Some cases, they increase the speed of reactions that would otherwise occur slowly.
Proteins
• Enzymes are involved in nearly all metabolic processes.
• The activities of enzymes depend on the temperature, ionic conditions, and the pH of the surroundings.
Enzymes act like a lock and key to facilitate chemical reactions within a cell.
The structure of Lipids
• Lipids are large biomolecules that are made mostly of carbon and hydrogen with small amount of oxygen.
• Fats, oils, waxes, and steroids are all lipids.
• They are insoluble in water because their molecules are nonpolar and are not attracted by water molecules.
Lipids
• Common type of lipid, three fatty acids linked with a molecule of glycerol.
• A fatty acid is a long chain of carbon and hydrogen.
• Saturated fatty acid- when each carbon to carbon bond is form by single bond.
• Unsaturated fatty acid- when there is a double bond between to carbons in a chain.
Lipids
• Cells use lipids for energy storage, insulation, and protective coverings.
• Lipids are the major components of the membranes that surround all living cells.
Lipids
The structure of Nucleic Acids
• A nucleic acid is a complex biomolecule that stores cellular information in the form of a code.
• Nucleic acids are polymers made of smaller subunits called nucleotides.
• Nucleotides consist of carbon, hydrogen, nitrogen, and phosphorus atoms arranged in three groups.
• Nitrogenous base, a simple sugar and a phosphate
Nucleic Acids (DNA)
• Nucleic acid DNA, which stands for deoxyribonucleic acid.
• DNA contains the instructions used to form all of an organism’s enzymes and structure.
• DNA forms the genetic code that determines how an organism loos and acts.
• DNA is passed every time a cell divides and from one generation of an organism to the next.
Nucleic Acid (RNA)
• RNA is another important nucleic acid. Stands for ribonucleic acid.
• RNA forms a copy of DNA for use in making proteins.
• The chemical differences between RNA and DNA are minor but important.